材料科学
印刷电路板
热导率
导电体
数码产品
氮化硼
复合材料
电介质
柔性电子器件
光电子学
功率密度
热传导
电子设备和系统的热管理
介电损耗
热阻
电导率
热的
可靠性(半导体)
填料(材料)
工程物理
电力电子
电气工程
电子线路
电磁干扰
机械工程
弯曲
消散
领域(数学)
氮化物
电磁场
电子工程
介电强度
功率(物理)
集成电路
作者
Zikang Yu,Fan Gao,Xulei Wu,Z. Huang,Jian Xu,Z. Zhao,Rui Zhou,Sijie Liu,Ye Liu,Huatao Wang
摘要
ABSTRACT The field of flexible electronics has flourished in recent years. Among its key elements, the flexible printed circuit (FPC) stands out as a fundamental building block, forming a circuit system. However, as power density continues to increase, issues related to heat dissipation and electromagnetic interference become increasingly prominent. Together, these factors pose growing challenges to the reliability of FPCs. In this paper, we introduce a method for preparing a flexible printed circuit using hexagonal boron nitride (h‐BN) and polyurethane (PU). The resulting h‐BN/PU‐based flexible printed circuit (hBP‐FPC) achieves high thermal conductivity, low dielectric loss, and robust bending resistance. The BN filler endows hBP‐FPC with significant thermal conductivity anisotropy. The in‐plane thermal conductivity of the prepared hBP‐FPC material reaches 4.1 W (m K) −1 , and the cross‐plane thermal conductivity is 1.4 W (m K) −1 . A significant temperature reduction (7.1–19.2°C) is achieved in the hBP‐FPC compared to commercial FPC over the power density range of 0.125–0.375 W/cm 2 . This study provides a promising strategy for developing high‐performance substrates for next‐generation high‐power‐density flexible electronics.
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